|Publication number||US7617068 B2|
|Application number||US 11/584,290|
|Publication date||Nov 10, 2009|
|Filing date||Oct 20, 2006|
|Priority date||Oct 20, 2006|
|Also published as||US20080097720|
|Publication number||11584290, 584290, US 7617068 B2, US 7617068B2, US-B2-7617068, US7617068 B2, US7617068B2|
|Inventors||Tony Tadin, Arjen Sundman|
|Original Assignee||Amfit, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (33), Referenced by (35), Classifications (17), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
1. Field of the Invention
The present disclosure relates to object contour measurements, and more particularly, to methods for determining mobility of different regions of a foot.
2. Description of the Related Art
Mobility, i.e., a difference in the position of a structure of a foot between loaded and unloaded states, is an important measurement, especially for determining the support needs of a person. The mobility of various areas of the foot vary from person to person. A relatively more mobile foot will flex more during ambulation (walking) than the more rigid foot. A foot with more mobility is also more likely to pronate excessively. This can result in foot instability and undo fatigue, which may result in stress, foot, knee and/or back injury.
The relative mobility of a foot is therefore important information when trying to understand any particular foot's needs for support in gait. This can be an especially powerful piece of information when trying to determine the proper footwear for a given foot. In addition, this information is helpful in determining what type of foot orthotic and the amount of support needed, in the range of rigid to semi-flexible to soft. A retailer with knowledge of the customer's mobility would be able to properly recommend a shoe and presumably have a sales advantage.
There is a need for an apparatus and method for determining the relative mobility of various areas of an object such as a foot.
A method for determining a mobility of an object, e.g., a foot, comprising: measuring at least a portion of a shape of the object under a first weight load; measuring the at least the portion of the shape of the object under a second weight load; and comparing the measurement under the first weight load to the measurement under the second weight load, thereby determining a mobility of at least the portion of the object.
Another embodiment includes a method for determining a mobility of an object, comprising: measuring a first elevation from a reference plane of at least one location on an object under a first weight load; measuring a second elevation from the reference plane of the at least one location on the object under a second weight load; and determining a mobility of the object at the at least one location based on a difference between the first elevation and the second elevation.
The reference plane is preferably a surface platform.
Optimally, mobility is determined by the formula:
(Object Elevation at Initial Loaded State at (X,Y))−(Object Elevation at Second Loaded State at (X,Y))=(Mobility of Foot at (X,Y))
The elevation measurement is taken along an axis perpendicular to the reference plane.
The method further comprises displaying the mobility to a user, customer and/or physician. The displaying preferably includes providing a visual indication of mobility characteristics across a surface of the object.
The method further comprises wherein at least one location is a plurality of locations arrayed on a surface of the object.
The method wherein each the measuring step uses a measurement system selected from the group consisting of: one or more gauge pins that contact a surface of the object, and one or more swing sensor arms.
Optionally, the method wherein each the measuring step uses an optical scanner that incorporates a light source to determine the elevation, wherein the light source is selected from the group consisting of: a structured light, a laser light source and a combination thereof.
Alternatively, the method wherein the measuring step uses a pattern that is adhered or conformed to the foot and is captured by an imaging device (e.g., camera, chemical or digital) and postprocessing to evaluate the surface of the foot. One such pattern is applied via a sock with stripe patterns on its which utilizes a camera to evaluate the shape of the stripes to determine the shape of the contour of the foot. Another embodiment, involves the use of a hand-held digital camera for creating a grid of sorts without a sock along with a lens having a built-in grid capability for measuring the foots angulation and geometry.
Alternatively, the method wherein each the measuring step uses an optical scanner that includes a camera to evaluate the surface of the foot.
The method wherein each the measuring step uses a pressure measurement to characterize the surface of the foot.
The method further comprising: comparing the mobility of the at least one location of the object with a mobility of a reference object.
The method further comprising designing, based on the mobility, a medical treatment selected from the group consisting of: an orthotic intervention and a surgical procedure.
The method further comprising selecting, based on the mobility, a support device selected from the group consisting of: footwear and an insole.
The method further comprising transmitting the visual indication of mobility characteristics to a remote location.
A method of evaluating the effectiveness of a proposed orthotic intervention, comprising: determining a desired mobility of at least a portion of a foot; placing the foot in a position that creates the desired mobility; determining an actual mobility of at least the portion of the foot by measuring at least a portion of a shape of the foot under a first weight load; measuring the at least the portion of the shape of the foot under a second weight load; and comparing the measurement under the first weight load to the measurement under the second weight load, thereby determining the actual mobility of at least the portion of the foot; and comparing the actual mobility to the desired mobility to determine whether the desired mobility has been achieved.
Optimally, the foot is placed in the position by inserting a mechanical support under a selected portion of the foot.
A computer-readable medium having computer-executable instructions for executing a method comprising the steps of: measuring a first elevation from a reference plane of at least one location on an object under a first weight load; measuring a second elevation from the reference plane of the at least one location on the object under a second weight load; and determining a mobility of the object at the at least one location based on a difference between the first elevation and the second elevation.
The computer-readable medium wherein the method further comprises displaying the mobility to a user, customer and/or physician.
The computer-readable medium wherein the step of displaying includes displaying information selected from the group consisting of: the first elevation, the second elevation, the mobility, and any combination thereof.
The computer-readable medium wherein the method further comprising designing a corrective treatment based on the mobility, and displaying the corrective treatment to a user.
The computer-readable medium wherein the corrective treatment is selected from the group consisting of: an orthotic intervention, a support device, and a surgical procedure.
The patent or application file contains at least one drawing executed in color. Copies of thie patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
The present disclosure provides an apparatus and method for determining a mobility of an object such as a foot by measuring an elevation or height of one or more points on the plantar surface of the foot, for example under the medial longitudinal arch, in at least two states: i) an unloaded or minimally loaded state and ii) a fully loaded state. The difference in the heights of each point in the loaded and unloaded states is used as an indicator of the midfoot mobility. It is the objective of the present disclosure to set forth a method of using these measurements in establishing relative mobility of various areas of the foot.
Referring to the drawings and, in particular,
In operation, the carriage assembly is moved in a left-to-right direction along plate 110. Laser 140 transmits its emission against mirror 145 and through transparent plate 110 onto the subject surface of foot 105. An image of the surface is transmitted through transparent plate 110 onto image mirror 135, through red pass filter 130, and is viewed and captured by camera 125. The structure and operation of optical contour digitizer 100 is further described in U.S. patent application Ser. No. 10/407,925, now U.S. Pat. No. 7,068,379, which is incorporated by reference herein.
The devices described above in conjunction with
In a preferred method, one or more points are measured under the plantar aspect of a foot, preferably under the medial longitudinal arch. This measurement is preferably done at or about the apex of the arch and medial of the longitudinal midline of the foot. The measurement may also be performed under the medial or lateral heel to evaluate mobility of the calcaneous or the forefoot.
At least two measurements are performed at each point on the subject surface of the foot. A first measurement is performed at a point with the foot unloaded or minimally loaded, and a second measurement is performed in that same point with the foot supporting a selected loading. In a preferred embodiment, the second measurement may be performed with the foot “fully loaded”, i.e., as supporting full body weight. The load on the foot may be any selected amount of weight, or any load representing various positions of the body, such as sitting, crouching, etc. It may also be desirable in some cases to measure the foot with all the body's weight on one foot or in an overloaded state to see what the foot does under extreme stress. Although two measurements are described for each point, additional measurements may be taken for each point at various load amounts.
There are many existing technologies to take a measurement of this sort. These technologies include optical scanning, utilizing light such as laser light, and reflected or structured light, and contact digitizing, where one or more gauge pins contact the subject surface and a linear measurement is made at each gauge pin's location. Examples of these technologies are discussed above. Additional technologies include: i) an array of sensor arms, e.g., swing arms, which are translated along an axis whose radial position can be used to evaluate elevation, and ii) impression foam or other shape-memory materials, where two impression are made of the foot and the resulting impressions are measured. One could also make a fully manual measurement of the arch or a simple mechanism can be devised to give an indication of the arch height and mobility.
In a preferred embodiment, a contact digitizer such as gauge pin digitizer 200 is used to make the measurements. A contact digitizer is ideally suited to this type of measurement as it has the ability to support the foot during measurement, has a built-in datum surface (i.e., its top plate), is highly accurate, and is able to provide closely correlated data points in the two weight states required.
For the initial measurement, the unloaded or minimally loaded foot is placed on top surface 210 of contact digitizer 200. Gauge pins 215 are urged upwards against the undersurface of the foot. The relative heights of each of gauge pins 215 is noted. This is preferably done using a processor to note and store each gauge pin's height. For the second measurement, the subject foot resting on surface 210 has normal body weight applied to it. Gauge pins 215 are once again urged upwards against the undersurface of the foot and the relative heights noted.
After data has been collected, at least two data sets result. A first data set includes height or elevation measurements of one or more points, i.e., locations, on the underside of the foot in an unloaded or minimally loaded state. A second data set includes height measurements of one or more points on the underside of the foot in a selected or fully loaded state. Each point represented in the first data set should also be represented in the second data set.
In a preferred embodiment, a large array of data points are measured, in order to have a complete picture of the elevation of each area of the foot. This can be accomplished using, for example, digitizer 200. In another embodiment, an optical digitizer, such as digitizer 100, can provide a continuous measurement of elevation over all areas of the foot.
Depending on the measurement methodology, the data sets may contain as few as one or many numbers indicating the relative heights of the foot in one or more locations. The contact digitizer records the heights over a wide area of the plantar aspect of the foot. Preferably, each data set represents an array of points on the underside of the foot, so that an accurate determination of the deformation of the foot at various points can be determined. By analyzing the differences between the data from the unloaded and loaded foot, a determination of the relative mobility of the foot in the region analyzed can be made.
In one embodiment, if the mobility of the arch of a given foot needs to be determined, the foot is measured twice, i.e., once in an unloaded state and once in a loaded state. The elevations of the sample point(s) under the arch are compared. The resulting difference is then compared against a data set of previously measured feet or an algorithm based on known foot dynamics to make a determination of the relative foot mobility in that foot's arch region, compared to a “normal” foot or compared to a foot having selected characteristics. Similarly, the data point(s) could be under the medial or lateral heel to evaluate mobility of the calcaneous or the forefoot to evaluate forefoot varus/valgus in various weight states.
The apparatus used in the method described herein may include a controller 122, 222 for taking measurements, calculating the data set from each set of measurements, and/or providing mobility data to a user. The controller 122, 222 preferably includes a computing platform, such as a personal computer, a mainframe computer, or any other type of computing platform that may be provisioned with a memory device, a CPU or microprocessor device, and several I/O ports. Software instructions for carrying out the methods described herein are stored in the memory device, and executed by the CPU or microprocessor. The software is capable of developing data which can be used to determine the corrective amount required as a function of the foots mobility. The controller 122, 222 may also include a display or other device for providing mobility information. In another embodiment, mobility data and/or the display may be transmitted to a remote user.
Mobility information may be provided to the user as raw data, or as a data set, such as in spreadsheet form, showing each height measurement and indicating the measurement location and load state. The data set may alternatively only include calculated mobility measurements, i.e., differences between heights of a point in various load states, for each measured point on an object's surface. The data set may also be provided to the user in various visual forms, such as is described below.
Comparing the elevation in a number of locations is illustrative of the analysis methodology and the information that can be gleaned from it. Looking at the elevation in
(Unloaded Foot Elevation at (X,Y))−(Loaded Foot Elevation at (X,Y))=(Mobility of Foot at (X,Y))
can be used to indicate foot function, malfunction and provide a wealth of information useful to the design of interventions to address various foot maladies especially for young children. This result can be compared with mobility data on a reference foot to determine whether support may be needed or helpful in this location of the foot. With early foot orthotic intervention the foot can realign itself.
A similar analysis at location E-26 in
Other regions of the foot can also reveal useful diagnostic information by comparing the loaded or semi-loaded foot's contour information against the same foot in an unloaded state. Some of these include: heel pronation, heel supination, Charcot foot, heel spur, dropped metatarsal head, rigid foot issues, and forefoot varus or valgus. Each of these conditions can be helped by using the information revealed by this process to design an effective orthotic intervention.
In another embodiment, elevation display 500, or mobility data in any other form, may be transmitted to a remote user. For example, display 500 or measurement information may be displayed to an off-site doctor or foot specialist for consultation. This may be accomplished via a teleconference, or by transmitting mobility data via a network such as an intranet or the internet, or by e-mail. Such remote transmission is useful, as a user may be able to receive advice from experts regarding orthotic or other medical intervention without the cost and delay associated with having additional live consultations or with sending a patient to numerous specialists.
The method may also be enhanced by including pressure measurements at various points on the underside of the foot. These measurements may be useful in providing information as to the pressure distribution on the surfaces of the foot that contact a surface, especially when the foot is loaded. In one example, top surface 210 of contact digitizer 200 may incorporate an array of pressure sensors embedded or resting on top surface 210. Pressure sensors would only register a reading for those surfaces in contact with top surface 210. The pressure readings may be displayed similarly to elevation display 500. The pressure readings may be displayed separately from elevation readings such as in elevation display 500, or may be incorporated into elevation display 500. For example, those areas showing a 0.00 or −0.01 elevation may be given pressure indications, so that a user can easily see the pressure distribution over the areas having no elevation. Although pressure measurements alone have drawbacks, because the are a two-dimensional measurement and therefore cannot measure mobility, such as arch drop mobility, pressure measurements can be useful as an enhancement to elevation mobility measurements.
A method is provided that includes the measuring and analyzing elevation data described above. The method may also include utilizing the resulting characterization of the foot's mobility to 1) indicate the need for orthotic intervention, and 2) provide suggestions on the nature of that intervention. For example, it can be determined from the exemplary elevation data shown in
The method may also include the additional step of providing validation of an adjustment being made to the foot. For example, if used in conjunction with a gauge pin measurement device such as device 1000 of
For example, the user may input a selected orthotic support or otherwise input the dimensions of an orthotic support. Based on this input, software that is run by the processor will modify the mobility data. The modified mobility data may then be displayed, such as in a format similar to that shown in
The method may also be used in conjunction with a video teleconference or still images to assist in diagnosing and designing interventions for patients remotely. These images could be transmitted in any of a number of generally available technologies including, but not limited to, I/P, optical, and wireless.
For example, a user may take mobility measurements of a patient's foot as described above. These measurements may be transmitted to and displayed to a medical professional or expert who may be in a location remote to that of the patient and user. The patient can then get the benefit of the expertise of one or more professionals without having to physically travel to that professional to have mobility measured. Furthermore, the user in this embodiment need only know how to operate the system to take mobility measurement data.
When the mobility measurement data is transmitted to an expert, the expert may analyze the data to determine what type of intervention is recommended, if any. The software allows the expert (or any other user) to simulate various orthotic supports and display the mobility of the foot with that support. This feature allows the expert to test various supports and determine the ideal supports to recommend. A video camera may also be incorporated in the system described above to take images of the foot in various loaded states, so that the expert can visualize the position and loading of the foot that corresponds with received mobility measurement data.
Alternatively, the present disclosure comprises a method for determining a mobility of an object, such as a foot, comprising: measuring at least a portion of a shape of the object under a first weight load; measuring the at least the portion of the shape of the object under a second weight load, wherein the measuring of the object under either or both of the first and second weight loads utilizes a pattern that is adhered or conformed to the object and wherein the patterns are captured by an imaging device; and comparing the patterns measured from the first and second weight loads, thereby determining a mobility of at least the portion of the object.
Preferably, the imaging device is at least one device selected from the group consisting of: camera, chemical and digital.
The pattern is applied via a sock with a stripe pattern disposed thereon and wherein the imaging device is evaluates the shape of the stripes to determine the shape of the contour of the object.
Another embodiment of the present disclosure comprises a method for determining a mobility of an object, comprising: measuring at least a portion of a shape of the object under a first weight load; measuring the at least the portion of the shape of the object under a second weight load, wherein the measuring of the object under either or both of the first and second weight loads is carried out via an imaging device comprising a grid for measuring the patterns of the object under a first and second weight load, and wherein the patterns are captured by the imaging device; and comparing the patterns measured from the first and second weight loads, thereby determining a mobility of at least the portion of the object.
It should be understood that various alternatives, combinations and modifications of the teachings described herein could be devised by those skilled in the art. The present disclosure is intended to embrace all such alternatives, modifications and variances that fall within the scope of the appended claims.
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|U.S. Classification||702/139, 600/589, 356/601, 702/167, 600/300, 356/600, 356/2, 702/166, 600/587, 702/168, 702/138|
|International Classification||G01B5/20, G01B5/207, G01B7/287, G01B7/28|
|Oct 20, 2006||AS||Assignment|
Owner name: AMFIT, INC., WASHINGTON
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:TADIN, TONY;SUNDMAN, ARJEN;REEL/FRAME:018448/0395;SIGNING DATES FROM 20061019 TO 20061020
|Mar 14, 2013||FPAY||Fee payment|
Year of fee payment: 4
|May 10, 2017||FPAY||Fee payment|
Year of fee payment: 8